NASA Technical Memorandum 107254
/
Tensile Strength and MicrostructuralCharacterization of Uncoated and
Coated HPZ Ceramic Fibers
Narottam P. Bansal and Donald R. Wheeler
Lewis Research Center
Cleveland, Ohio
Robert M. Dickerson
NYMA, Inc.
Brook Park, Ohio
July 1996
National Aeronautics and
Space Administration
https://ntrs.nasa.gov/search.jsp?R=19960047999 2020-06-14T16:31:15+00:00Z
Trade names or manufacturers' names are used in this report for identification
only. This usage does not constitute an official endorsement, either expressed
or implied, by the National Aeronautics and Space Administration.
TENSILE STRENGTH AND MICROSTRUCTURAL
CHARACTERIZATION OF UNCOATED AND
COATED HPZ CERAMIC FIBERS
Narottam P. Bansal and Donald R. Wheeler
National Aeronautics and Space AdministrationLewis Research Center
Cleveland, Ohio 44135
and
Robert M. Dickerson
NYMA, Inc.
Brook Park, Ohio 44142
SUMMARY
Tensile strengths of as-received HPZ fiber and those surface coated with BN, BN/SiC, and BN/Si3N 4 have been
determined at room temperature using a two-parameter Weibull distribution. Nominally -0.4 [xrn BN and 0.2 larnSiC
or Si3N 4 coatings were deposited on the fibers by chemical vapor deposition using a continuous reactor. The averagetensile strength of uncoated HPZ fiber was 2.0-&-_0.56GPa (290-!-_81ksi) with a Weibull modulus of 4.1. For the BN coated
fibers, the average strength and the Weibull modulus increased to 2.39-&-_0.44GPa (346+64 ksi) and 6.5, respectively. TheHPZ/BN/SiC fibers showed an average strength of 2.0-L-_0.32GPa (290-&-_47ksi) and Weibull modulus of 7.3. Average
strength of the fibers having a dual BN/Si3N 4 surface coating degraded to 1.15+0.26 GPa (166+38 ksi) with a Weibullmodulus of 5.3. The chemical composition and thicknessof the fiber coatings were determined using scanning Auger
analysis. Microstructural analysis of the fibers and the coatings was carried out by scanning electron microscopy andtransmission electron microscopy. A microporous silica-rich layer-200 nm thick is present on the as-received HPZ fiber
surface. The BN coatings on the fibers are amorphous to partly turbostratic and contaminated with carbon and oxygen.
Silicon carbide coating was crystalline whereas the silicon nitride coating was amorphous. The silicon carbide and silicon
nitride coatings are nonstoichiometric, nonuniform, and granular. Within a fiber tow, the fibers on the outside had thicker
and more granular coatings than those on the inside.
1. INTRODUCTION
The HPZ ceramic fiber is an inorganic silicon carbonitride fiber manufactured from hydridopolysilazane polymer
via a pyrolytic process by Dow Coming Corporation. It has an oval cross section and is amorphous with a typical
elemental composition of 57%Si, 28%N, 10%C, and 4%0. The thermal expansion coefficient of HPZ fiber is
-3x10-6/°C (ref. 1 ). It has a desirable combination of tensile strength, elastic modulus, density, and electrical properties
and retention of these properties at temperatures up to -1400 °C (ref. 1), making it suitable for a variety of aerospace
applications. It is intended as a reinforcement in high performance composites with ceramic, metal and polymer matrices.The HPZ fiber surface is microporous and extremely reactive when in contact with aluminosilicate glass-ceramic
matrices at high temperatures. According to Brennan (ref. 2), diffusion of matrix elements such as Ba, Mg, Ai, Si, and
O through this porous surface layer occurs very rapidly, resulting in crystallization of the underlying HPZ fiber to silicon
oxynitride, Si2N20. The HPZ fiber surface needs to be protected with appropriate ceramic coating(s) in order to alleviatechemical reactions with ceramic matrices during composite processing and use and also, to provide a weak fiber-matrix
interface for toughened composites.
The primary objective of the present study was to investigate the effect of CVD ceramic surface coatings on the
strength of the HPZ fiber. This provides a data base for planned work directed at incorporating these coated fibers asreinforcement in celsian matrix composites. Another objective was to carry out microstructural and chemical analyses
of the fiber and the coatings. Room temperature tensile strengths of the as-received HPZ fibers and those coated with
BN,BN/SiC,andBN/Si3N4weremeasuredandtheWeibullstatisticalparametersdeterminedforeachtypeoffiber.Elementalcompositionsandthicknessof thefibercoatingsweredeterminedby scanningAugeranalysis.Themicrostructuralanalysesof thefibersandthecoatingsweredonebyscanningelectronmicroscopy(SEM)andtransmissionelectronmicroscopy(TEM).
2. MATERIALSANDEXPERIMENTALPROCEDURES
ThefiberusedinthepresentstudywastheX9-6371HPZceramicfiber,lotnumber031860,having1000denierandnominally500filaments/towandsuppliedbyDowComingCorporation.Thepolyvinylalcohol(PVA)sizingonthefiberswasremovedeitherbydippingthefiberbundleinboilingwaterforseveralminutesorinabunsenburnerflame.Singlefilamentswerecarefullyseparatedfromthefibertowfortesting.
All thecoatingsonthefiberswereappliedbyanoutsidevendorusingacontinuousCVDreactor.TheBNcoatingwasdepositedat-1000°Cutilizingaproprietaryprecursorandwasamorphoustopartlyturbostraticinnature.A thinovercoatingofSiCorSi3N4wasalsoappliedbyCVDtotheBN-coatedfibers.Thenominalcoatingthicknesseswere0.4_tmforBNand0.2_tmforSiCorSi3N4.
2.1ElectronMicroscopy
SurfacesoftheuncoatedandcoatedlooseHPZfiberswereexaminedusingscanningelectronmicroscopy(SEM).Forcross-sectionalanalysis,fibersweremountedinahightemperatureepoxyandpolishedbeforeexamination.SEMwasperformedusingaJEOLJSM6100operatingat15keV.Fibercross-sectionalthinfoilsfortransmissionelectronmicroscopy(TEM)werepreparedusingaproceduredevelopedforceramicfiberswhichinvolvesepoxypotting,slicing,polishing,dimplegrinding,andArionbeammilling.A thincarboncoatingwasevaporatedontothethinfoilsandtheSEMspecimensforelectricalconductivitypriortoanalysis.ThethinfoilswereexaminedinaPhilipsEM400Toperatingat 120keV.X-rayelementalanalysesontheTEMwereacquiredusinga Kevexthinwindowenergydispersivespectrometer(EDS)andanalyzer.
2.2.ScanningAugerAnalysis
TheelementalcompositionsofthefibernearthesurfaceandofthefibersurfacecoatingswereanalyzedwithascanningAugermicroprobe(FisonsModel31OF).Thefibersforthisanalysisweremountedbypressingintoindiumfoiltominimizeelectricalchargingduringanalysis.Depthprofilingwasperformedbysequentialion-beamsputteringandAugeranalysis.TheionetchingwasdonewithanAr+beamof3kVacceleratingvoltageandbeamcurrentof420nAandrasteredover~l mm2areaonthespecimen.Thebeamwasoriented48°tothespecimennormalandwasobliquetothefiberaxis.TheetchrateinTa205undertheseconditionswas0.41nm/s.
AESanalysiswasperformedwiththesamplenormal60°totheelectronbeamandparalleltotheanalyzeraxis.Thebeamwasrasteredovera1btm 2 area at 100 kX during analysis and centered on the fiber. The beam voltage was 1.5 kV
and the beam current was -5.5 nA. Spectra were taken in integral ( as opposed to derivative) form, and depth profiles
were created by plotting peak areas against ion etch time. The atomic concentrations were calculated by dividing the peak
areas by sensitivity factors derived from spectra of several standard materials containing that element, then scaling the
results to total 100 percent. The sensitivity factors used for each element should not be trusted to better than +20 percent.
The depth scale is from the Ta205 calibration and has not been adjusted for the actual etch rate of the material. Only thefibers with smooth surface coating, rather than those having thick and rough coating morphologies, were used for Augeranalysis.
2.3. Tensile Strength Measurement
Room temperature tensile strengths of the individual filaments were measured in ambient atmosphere with an
Instron machine (Model # 4502) at a constant crosshead speed of 1.27 ram/rain (0.05 in./min). A single filament was
mounted on a paper tab with an epoxy. The side portions of the tab were cut with a hot wire just before application of
the load producing a fiber gage length of 2.54 cm (1 in.). The fracture pieces were captured by applying a water based
lubricatingjellytothefiberpriortotestthuscausingthefragmentstostickontissuepaperplacedbehindthetestfiber.Twentyfilamentsofeachtypeoffiberweretested.SomeoftheHPZfiberswereroundbuthollowandwerenotincludedinstrengthmeasurements.
A largevariationin thefiberdiameterwasobserved,althoughthemanufacturerreportsanaveragevalueof-10to12ktm.Becauseoftheiroblongshape,themethodasshowninfigure1,wasusedtocalculatethecross-sectionalareaofthefiberfollowingthetensiletest.AZeissopticalmicroscopeatamagnificationof500Xwasusedtomeasureboththemajor(D)andtheminor(d)diametersatoneofthefracturesurfacesofthefiber.Possibly,butmostlikelynot,theprimaryfracturesurfacewasviewedinthemicroscope.Thecross-sectionalsurfaceareawascalculatedfromtheequation:
Fibercross- sectionalarea= AreaA +AreaB+AreaC
= (l/2)n(d/2)2+(D- d)d+(1/2)_(d/2)2
= gdZ/4+(D- d)d
(l)
3. RESULTS AND DISCUSSION
3.1 Electron Microscopic Analysis
3.1.1 HPZ fiber.--SEM micrographs showing the surface and cross-section of as-received, desized HPZ fibers are
given in figures 2 and 3, respectively. The fiber surface is fairly smooth and featureless. The fiber cross-section is oblong
with average major and minor diameters of 14.4 and 8.4 _tm ("D" and "d" in fig. 1), respectively. It should be noted thatthe HPZ fibers often crack during the early stages of cross-sectional polishing due to a lack of constraint in the epoxymounts. A core and rim structure in the fiber cross-section is also revealed. This is even more apparent in the TEM
micrograph shown in figure 4. The speckled contrast within the rim region is due to under-focussed imaging conditionsused to enhance contrast and is not indicative of the scale of any actual structure. The average thickness of the fiber rim,
which is seen to be microporous, was determined to be -360 nm. Electron micro-diffraction patterns taken from both
the core and rim regions (fig. 4 insets) are diffuse rings indicating an amorphous to nanocrystalline crystal structure. EDS
compositional spectra taken from the core and rim regions are shown in figure 5. The fiber core is rich in Si and N andcontains small amounts of C, O, AI, and CI. The rim is mostly Si and O, but some C, N, and Ai were detected, as well.
3.1.2 HPZ/BN fiber.--An SEM micrograph of a fiber after coating with BN is given as figure 6(a). Cross-sectional
micrographs gave poor contrast, due to the low signal yield from the BN, due to its low atomic weight. The coating canspall off from the fibers when broken in bending to reveal multiple layers (fig. 6 (b)). The outermost layer of BN was
often quite nodular, as can be seen in figure 6(a) and (b). TEM dark field images of the BN layer revealed a radial structurenot visible in bright field images (fig. 7). Microdiffraction patterns from the BN (fig. 7 inset) showed a turbostratic
structure.
3.1.3 HPZ/BN/SiC fiber.--The nodules in the BN layer remain or, often, are enhanced by the subsequent coating
of SiC (fig. 8). The density of the nodules varies considerably from fiber to fiber, but is more consistent along eachindividual fiber. The coated nodules are primarily somewhat less than 1 I.tm in diameter. Sharp contrast is observed
between the fiber core, fiber rim, BN coating, and SiC coating in polished cross-sections (fig. 9). The thickness of the
outer SiC coating varies from fairly uniform to quite variable and granular. The BN coating thickness varies from
approximately 360 to 800 nm between fibers. The SiC coating ranges from about 140 nm to as thick as 5 ktm when a
granular cluster is attached. Within a tow, the fibers on the outside had thicker and more granular coatings than those onthe inside. TEM cross-sections (figs. 10 and 11) reveal the layered structure of the coating. No structural or chemical
changes are observed in the fiber cores and rims. A thin band of relatively featureless material is found at the rim/BN
interface (fig. 10). This band ion mills more quickly during sample preparation than the surrounding material and mightbe silica-rich. This region is too narrow to obtain unambiguous crystallographic or compositional information in a
conventional TEM, however. Some slight widening of the band is often seen at the tighter radius regions of the fibers,
but these regions are usually thinned away during preparation. The BN coating often hints of layering and gives
diffraction patterns consistent with a loosely turbostratic structure seen in the as-received fibers. Columnar SiC grains
are seen just outside the BN layer. Electron diffraction patterns (fig. 10 inset) indicate that the SiC is crystalline.
Diffraction patterns taken from the SiC layers were consistent with a mixture of primarily hexagonal polytypes. Thenodular material consists of cores of BN surrounded by columnar SiC (fig. 11 ). EDS spectra taken from the BN layer
andthenodulecoresarequitesimilarasarethespectrafromvarioussectionsof the SiC coating. The inner coating was
relatively rich in detectable C and N and had some O, AI, and Si. It should be noted that boron is not detectable using
the present methods and that some small signals may come from neighboring material. The EDS spectra from the outer
layers were those of SiC.
3.1.4 HPZ/BN/Si3N__ 4. fiber.--The outer coating on these fibers is also quite granular (fig. 12). More flaws in the
smooth underlying Si3-N4-tayer are observed, however. The nodule sizes are very similar to those of the BN/SiC-coatedfibers. Outer coating thicknesses vary more widely than the BN/SiC-coated fibers (fig. 13). The clusters attached to some
fibers nearly double the fiber dimensions. Several flaws in relatively thin Si3N 4 layers were observed (arrow in fig. 13(a)).The tows showed similar coating quality and thickness variation as in the BN/SiC coated fibers. Fibers towards the
outside of each tow have a thicker and more granular coating than the fibers on the inside. No structural or compositional
changes in the fiber rims and cores were detected in the TEM (fig. 14). A thin band of more easily thinned material at
the rim/BN interface is seen in these fibers as well. Often, the Si3N 4 layer was missing completely (fig. 14(a)). The
transition from orderly to granular coating structures was often indistinct (fig. 14(b)). While the granules consisted of
core and rim structures, the constituents were less distinct crystallographically than the BN/SiC-coated fibers.
Compositionally, the BN inner layers and granule cores yielded EDS spectra essentially identical to those of the BN in
the BN/SiC-coated fibers. The outer layers are relatively rich in Si and N, as would be expected, and contained more CI
than was found elsewhere. The smooth BN layers were loosely turbostratic while the granule cores gave diffraction ring
patterns consistent with nanocrystalline hexagonal BN. The Si3N 4 layers were not distinctly crystalline as seen from the
electron diffraction pattern (fig. 14(b) inset).
3.2. Scanning Auger Analysis
Elemental composition depth profiles, as obtained from scanning Auger analysis, of HPZ fibers and those coated
with BN, BN/SiC, and BN/Si3N 4 are shown in figures 15(a) to (d). The surface of the uncoated HPZ fiber consists of
an SiO2-rich layer having a thickness of-200 nm. The elemental composition (at %) in the bulk of the fiber is -49%Si,- 11%C, -37%N, and -3 %0. The BN layer in the HPZ/BN fiber is -0.3 _tm thick. It may be somewhat rich in boron and
is contaminated with -10 at % of oxygen and - 3 to 5 at % of carbon. At the fiber/coating interface, there is an SiO2-rich
layer about 200 nm thick. The HPZ/BN/SiC fiber has ~ 150 nm thick layer of Si-rich SiC followed by -400 nm thick layer
of BN. This BN coating appears to be nearly of stoichiometric composition, rather than boron rich, and is much less
contaminated with oxygen than the BN layer in HPZ/BN fiber. This is again followed by ~ 150 nm thick SiO2-rich layer
at the coating/fiber interface. The _N/Si3N 4 fiber has ~300 nm thick layer of Si-rich silicon nitride along with lowlevel contamination of oxygen. This is followed by -800 nm thick layer of boron-rich BN which is contaminated with
-25 to 30 at % of carbon and -5 at % of oxygen. A SiO2-rich layer, -200 nm thick, is again present at the fiber/coating
interface. The thickness of this SiO2-rich layer, ranging from 0.2 to 1.0 _tm, is reported (ref. 6) to vary from fiber to fiberand also from batch to batch of the HPZ fibers, and depends on the fiber processing conditions.
3.3. Tensile Strength
The strength of ceramic fibers is determined by the statistical distribution of flaws in the material. The tensile strengthof ceramic fibers is generally analyzed on the basis of the well known Weibull statistics (ref. 7), expressed by the
empirical equation:
Ps=l-P(t_)=exp-V c-is u ¢s0 (2)
where Ps is the survival probability (P(c) = 1 - Ps is the failure probability) of an individual fiber at an applied stress of
_, V is the fiber volume, t_u is the stress below which failure never occurs, t_o is the scale parameter, and m is the shape
or flaw dispersion parameter, m and c o are constant for a given material. Assuming Ou = 0 and uniform fiber diameteralong the length L corresponding to the volume V, eq. (2) can be rearranged as:
In ln(1/P s) = In ln[1/(1 - P(c))] = m In _ + constant (3)
4
Theexperimentaldata can be ranked in ascending order of strength values and the cumulative probability P(ci) can be
assigned as
P(t_i) = i/(l + N) (4)
where i is the rank of the tested fiber in the ranked strength tabulation and N is the total number of fibers tested. A least-
squares linear regression analysis can then be applied to a plot of [lnlnl/P s] vs. In(o). The slope of this analysis is the
Weibull modulus m. The median strength of the fiber, ¢_0.5 (corresponding to Ps = 0.5), depends on its length L and is
expressed by the expression:
in ¢_0.5= -(l/m) In L + constant (5)
According to eq. (5), a plot of In ¢_0.5vs. In L should be linear with a slope of-1/m.
The In In (l/Ps) vs. in a Weibull probability plots for room temperature tensile strength of uncoated HPZ fibers andthose having surface coatings of BN, or BN/SiC are shown in figure 16. Similar Weibull probability plot for BN/Si3N 4
coated HPZ fibers is given in figure 17. Values of Weibull parameters obtained from linear regression analysis for HPZ
fibers with different coatings are given in table I. The average tensile strength of as-received (after sizing removal) HPZfiber is 2.0-2_0.56 GPa (290-+81 ksi) and the value of m is 4.1. The manufacturer's information data sheet (ref. 1) reports
values of 1.72 to 2.07 GPa (250 to 300 ksi) for the room temperature tensile strength of these fibers. Similar strength
values of HPZ fibers have also been reported by Takeda et al. (ref. 3). However, Villalobos et al. (ref. 4) report tensile
strengths of 1.5 to 1.8 GPa for two different batches of HPZ fibers where as Moorehead and Kim (ref. 5) give 2.83+0.87
GPa as the room temperature tensile strength of these fibers. The BN-coated fibers showed an increase in average tensile
strength as well as Weibull modulus to 2.39-2-_0.44 GPa (346+64 ksi) and 6.5, respectively. This may be due to theelimination of fiber surface flaws by the smooth BN coating. The HPZ/BN/SiC fibers showed the same average strength,
2.0-2-_0.32GPa (290-2-_47ksi), as the as-received fibers, but the value of m increased to 7.3. The average tensile strength
of the BN-Si3N 4 coated fibers degraded to 1.15+0.26 GPa (166+38 ksi), yet showed an m value of 5.3. Since the BNcoating on HPZ fibers resulted in an increase in tensile strength, the reduction in strength of the fibers having dual coatings
is probably due to exposure of the BN-coated fibers to high temperatures during chemical vapor deposition of siliconcarbide and silicon nitride or to large flaws in these layers. However, it is difficult to guess the exact temperatures
experienced by these fibers during CVD as the experimental conditions used during coating of the fibers are considered
to be proprietary and were not provided by the vendor. Room temperature tensile strength of the HPZ fibers is known
(ref. 5) to degrade after exposure to temperatures as low as 1000 °C for a few hours in air or argon atmospheres.
4. SUMMARY
Room temperature tensile strengths of as-received HPZ fiber and those surface coated with BN, BN/SiC, or BN/
Si3N 4 by CVD have been measured. The uncoated HPZ fiber showed an average tensile strength of 2.0-2_0.56 GPa(2905:81 ksi) and the Weibull modulus of 4.1. For the BN coated fibers, the average strength and the Weibull modulusincreased to 2.39+0.44 GPa (3465:64 ksi) and 6.5, respectively. The HPZ/BN/SiC fibers showed an average strength of
2.0!-_0.32 GPa (2905:47 ksi) and Weibull modulus of 7.3. The average strength of fibers having dual BN/Si3N 4 surface
coating degraded to 1.15_+0.26 GPa (166_+38 ksi) with a Weibull modulus of 5.3. Chemical compositions of HPZ fiber
and the surface coatings have been determined using scanning Auger analysis. Scanning electron microscopy and
transmission electron microscopy were used for microstructural analysis of the fibers and the coatings. A microporous
silica-rich layer, -200 nm thick, is present on the HPZ fiber surface. The BN coatings are amorphous to partly turbostraticand contaminated with carbon and oxygen. Silicon carbide coating was crystalline whereas the silicon nitride coating
was amorphous. Silicon carbide and silicon nitride coatings are non-stoichiometric, nonuniform and flaky. Within a fibertow, the fibers on the outside had thicker and more granular coatings than those on the inside.
5. CONCLUSIONS AND FUTURE WORK
It may be concluded that because of low tensile strength of BN/Si3N 4coated HPZ fibers, ceramic matrix compositesreinforced with these fibers will not exhibit high strengths. Barium aluminosilicate glass-ceramic matrix composites
reinforced with uncoated and coated HPZ fibers have been fabricated. Measurement of their mechanical properties at
room and elevated temperatures is in progress. The fiber/matrix interface and the microstructures of these composites
are also being investigated. The results of these findings will be reported in the near future.
ACKNOWLEDGMENTS
Thanks are due to Dr. Frank Honecy for the scanning Auger analysis and to Greg Selover for his assistance with the
tensile strength measurements.
REFERENCES
1. Dow Coming (R) X9-6371 C-2 Sized HPZ Ceramic Fiber Test Report Sheet, May 17, 1991.
2. Brennan, J.J., Interfaces in BN Coated Fiber Reinforced Glass-Ceramic Matrix Composites, Scr. Met. Mater., 31 [8],
pp. 959-964 (1994).
3. Takeda, M., Imai, Y., Ishikawa, T., Kasai, N., Seguchi. T., and Okamura, K., Thermomechanical Analysis of the
Low Oxygen Silicon Carbide Fibers Derived from Polycarbosilane, Ceram. Eng. Sci. Proc., 1417-8],
pp. 540-547 (1993).
4. Villalobos, G.R., Starr, T.L., Piotrowski, D.P., and Sleboda, T.J., Advanced Dielectric Fiber Properties, Ceram. Eng.
Sci. Proc., 1417-8], pp. 682-689 (1993).
5. Moorhead, A.J. and Kim, H.-E., Strength of SiC- and Si-N-C-Ceramic Fibers Exposed to High-Temperature
Gaseous Environments, in "Composites: Design, Manufacture, and Application," S.W. Tsai and G.S. Springer,
Eds., Proc. 8th Int. Confr. Comp. Mater. (ICCM/VIII), SAMPE, pp. 23D1-23DI 1 (1991).
6. Zangvil, A., Chang, Y.-W., Finnegan, N., and Lipowitz, J., Effect of Heat Treatment on the Elemental Distribution
of Si, C, N, O Fibers, Ceram. Int., 1814], pp. 271-277 (1992).
7. Weibull, W., A Statistical Distribution Function of Wide Applicability, J.Appl. Mech., 18 [9], pp. 293-297 (1951 ).
TABLE 1.---WEIBULL PARAMETERS FOR ROOM TEMPERATUREa
TENSILE STRENGTHS OF UNCOATED AND COATED HPZ FIBERS
Fiber Average strengthcoating GPa (ksi)
None 2.0-I-0.56 (290-__81)
BN 2.39-&-0.44(3462-64)
BN-SiC 2.0-L-0.32 (290-&47)
BN-Si3N 4 1.15!-0.26 (166-2:38)
IFor 1 in. test gage length.
WeibuU to 50 percent survivalmodulus GPa strength
m GPa (ksi)
4.1 2.21 2.02 (293)
6.5 2.56 2.42 (351)
7.3 2.13 2.03 (294)
5.3 1.25 1.16 (169)
D
I= D-dI
Cross-sectional area = A + B + C
¢r (d/2)2 + (D-d)d + _ (d/2) 2= 2
_d2+ D-d= 4 d
Figure 1 .--Calculation of cross-sectional area of HPZfiber.
Figure 2.---SEM secondary electron micrograph showing surface of desizedHPZ fiber.
Figure3.---SEMbackscatteredelectronmicrographshowingpolishedcross-sectionofdesizedHPZfiber.
Figure4.toTEMbrightfieldimageofHPZfibercoreandrimincross-section.Electronmicro-diffractionpatternsfromthecore(left)andrim(right)areinset.
0.000 20.450 5.040
0.000 20.450 5.040Figure5.---SEMEDSspectraofHPZfiberpolishedcross-section.(a)Fiber
core.(_Rim.
9
Figure6.---SEMsecondaryelectronmicrographofHPZfiberwithBNcoating.(a)Viewedfromtheside.(b)Showinglayering.
lO
Rim
Figure 7.--TEM dark field image of HPZ fiber with BN coating in cross-section.Electron micro-diffraction pattern showing turbostratic structure in the BN is inset.
Figure 8.---SEM secondary electron micrograph of HPZ fiber with BN and SiCcoatings viewed from the side.
]!
Figure 9.---SEM backscattered electron micrograph showing polished cross-section of HPZ fiber with BN and SiC coatings.
Core
i i200 nm
Figure 10.--TEM bright field image of HPZ fiber core and rim and BN and SiC
coatings in cross-section. Electron micro-diffraction pattern from the SiCcoating is inset.
]2
Figure 11 .--TEM bright field image of HPZ fiber with BN and SiC coatings in cross-section showing nodular core and rim structure.
Figure 12._EM secondary electron micrograph of HPZ fiber with BN andSi3N 4 coatings viewed from the side.
t3
Figure 13._EM backscattered electron micrograph of HPZ fiber with BN andSi3N 4 coatings viewed in polished cross-section. (a) Showing thin coating.(b) Showing thick, granular coating.
14
ImJ
200 nm
(a)
Figure 14.--TEM bright field image of HPZ fiber with BN and Si3N 4 coatings in cross-section. (a) Si3N4 coating is missing. (b) Showing nodular core and rim structure;micro-diffraction pattern from the Si3N4 is inset.
15
5O: 40
0
g 3o0
._ 20Eo 10
0
(_
6O
". Si
__ C _
NI I I I
0 10 20 30 40
Depth, nm
5O
o 40COo 30O
"o_ 20
10
o
(b)
B
N -. ' Si .J
__ '! J
t
i, N
0 I -.'
0
O .-- -_
- J
100 200 300 400 500
Depth, nm
6O
5O
40t-
O°30 -._oE 20 -O
lo -
0 10 100
(c)
_Si-- B _
--C;-"" i'" N" -
• / N.
-\ %.0 / ,/_!,I--F_'"-F7 [ _, I i200 300 400 500 600 700
Depth, nm
6O
50
_ 4o0o 30
E 2O0
_1o
0
t
L_ _ .'f<'c-I1 i/,o, ,,\, o ' / o_
0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4(d) Depth, nm
Figure 15.---Depth profiles of various elements.(a) HPZ. (b) HPZ/BN. (c) HPZ/BN/SiC.(d) HPZ/BN/Si3N 4 fibers obtained fromscanning Auger microprobe.
)6
2.0
1,0
0.0
"- -1.0v
D
¢..
-2.0
-3.0
c a b
---0--
---tD--HPZ
HPZ/BNHPZ/BN/SiC
--4.0 L I , I L I
10 0 101
Strength, GPa
Figure 16.mWeibull probability plot for room temper-
ature tensile strengths. (a) HPZ. (b) HPZ/BN. (c) HPZ/BN/SiC fibers.
0.0
_" -1.0ct-
-2.0
<>
/<>
<>
<>
2.0 --
1.0 --
-3.0 --
-4.0 l , i , i _,1 l , = , _,J,I
10-1 10 0 101
Strength, GPa
Figure 17.mWeibull probability plot for room temper-ature tensile strength of HPZ/BN/Si3N 4 fiber.
17
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July 1996 Technical Memorandum
5. FUNDING NUMBERS4. TITLE AND SUBTITLE
Tensile Strength and Microstructural Characterization of Uncoated and Coated
HPZ Ceramic Fibers
6. AUTHOR(S)
Narottam P. Bansal, Donald R. Wheeler, and Robert M. Dickerson
7. PERFORMING ORGANIZATION NAME(S) AND ADDRESS(ES)
National Aeronautics and Space Administration
Lewis Research Center
Cleveland, Ohio 44135-3191
9. SPONSORING/MONITORING AGENCY NAME(S) AND ADDRESS(ES)
National Aeronautics and Space Administration
Washington, D.C. 20546-0001
WU-505-63-12
8. PERFORMING ORGANIZATIONREPORT NUMBER
E-10312
10. SPONSORING/MONITORINGAGENCY REPORT NUMBER
NASA TM- 107254
11. SUPPLEMENTARY NOTES
Narottam P. Bansal and Donald R. Wheeler, NASA Lewis Reaserch Center; Robert M. Dickerson, NYMA, Inc., 2001
Aerospace Parkway, Brook Park, Ohio 44142 (work funded by NASA Contract NAS3-27186). Responsible person,
Narottam P. Bansal, organization code 5130, (216) 433-3855.
12a. DISTRIBUTION/AVAILABILITY STATEMENT
Unclassified - Unlimited
Subject Category 27
This publication is available from the NASA Center for AeroSpace Information, (301) 621-0390.
12b. DISTRIBUTION CODE
13. ABSTRACT (Maximum 200 words)
Tensile strengths of as-received HPZ fiber and those surface coated with BN, BN/SiC, and BN/Si3N 4 have been deter-
mined at room temperature using a two-parameter Weibuli distribution. Nominally -0.4 pin BN and 0.2 l.tm SiC or Si3N 4
coatings were deposited on the fibers by chemical vapor deposition using a continuous reactor. The average tensile
strength of uncoated Ht_ fiber was 2.0 + 0.56 GPa (290 + 81 ksi) with a Weibuil modulus of 4.1. For the BN coated
fibers, the average strength and the Weibull modulus increased to 2.39 + 0.44 GPa (346 + 64 ksi) and 6.5, respectively.
The HPZ/BN/SiC fibers showed an average strength of 2.0 + 0.32 GPa (290 + 47 ksi) and Weibull modulus of 7.3.
Average strength of the fibers having a dual BN/Si3N 4 surface coating degraded to 1.15 + 0.26 GPa (166 + 38 ksi) with a
Weibull modulus of 5.3. The chemical composition and thickness of the fiber coatings were determined using scanning
Auger analysis. Microstructural analysis of the fibers and the coatings was carried out by scanning electron microscopy
and transmission electron microscopy. A microporous silica-rich layer -200 nm thick is present on the as-received HPZ
fiber surface. The BN coatings on the fibers are amorphous to partly turbostratic and contaminated with carbon and
oxygen. Silicon carbide coating was crystalline whereas the silicon nitride coating was amorphous. The silicon carbide
and silicon nitride coatings are non-stoichiometric, non-uniform, and granular. Within a fiber tow, the fibers on the outside
had thicker and more granular coatings than those on the inside.
14. SUBJECT TERMS
Tensile strength; HPZ fiber; Electron microscopy; Scanning Auger analysis; Coatings
17. SECURITY CLASSIFICATIONOF REPORT
Unclassified
18. SECURITY CLASSIFICATIONOF THIS PAGE
Unclassified
19. SECURITY CLASSIFICATIONOF ABSTRACT
Unclassified
15. NUMBER OF PAGES20
16. PRICE CODE
A0320. LIMITATION OF ABSTRACT
NSN 7540-01-280-5500 Standard Form 298 (Rev. 2-89)Prescribed by ANSI Std. Z39-18298-102